JPH10502784A - Method for transmitting a signal between a mobile radio communication device and a fixed radio transmission / reception device and an apparatus for implementing the method - Google Patents

Abstract

(57) Summary The present invention relates to a method for transmitting a signal between a mobile radio communication device and a fixed radio transmission / reception device, and an apparatus for implementing the method. A radio space to be captured by a fixed radio transmitter / receiver, for example a radio telephone base station, is illuminated by two or more directional antennas (3, 4) each covering one partial radio space. In this case, the mobile radio transmitting / receiving device is adapted to be able to excite the directional antennas (3, 4) respectively in the partial radio space where the mobile part of the radio telephone is located, for example. (Diversity antenna). The present invention is advantageous because it can be used in the case of wireless telephones.

Description

DETAILED DESCRIPTION OF THE INVENTION mobile wireless communication device and the fixed radio transmitting / receiving device between device TECHNICAL FIELD The present invention for carrying out the method and method for transmitting a signal, the method according to the preamble of claim 1 And an apparatus for performing the method. BACKGROUND ART The range of a wireless communication device including mobile and fixed wireless transmission / reception devices, for example, a wireless telephone, is mainly determined by its transmission output and reception sensitivity. The transmission power is generally uniformly radiated in all directions, i.e. radiated approximately spherically, on the one hand in each environment and, on the other hand, the same range in each direction. Can be achieved. However, when observing individual points in time, from the perspective of a fixed wireless transmitting / receiving device, for example a base station of a radiotelephone, only a part of the transmission energy is in the direction of the mobile radio transmitting / receiving device, for example the movement of the radiotelephone. It is only emitted to parts. On the other hand, almost all of the transmitted energy is not used, which may impair unrelated equipment. For this purpose, a fixed radio transmitting / receiving device, such as one comprising a sharply focused directional antenna capable of concentrating available energy in the direction in which the mobile radio transmitting / receiving device currently exists. Is desired. However, this requires considerable expense both for the location of mobile devices, for example the moving parts of radio telephones, and for the correct orientation of the directional antenna. It is an object of the present invention to provide a method by which the transmission characteristics of a telecommunications device, in particular of a radiotelephone, between a mobile and a fixed radio transmitting / receiving device can be improved without cost. DISCLOSURE OF THE INVENTION According to the present invention, in a method based on the generic concept of claim 1, the above-mentioned problem can be solved by the method described in the characterizing part of claim 1. The type of diversity antenna is different and can be used to counter the fading effect and is known from German Utility Model No. 92 14 455. When the method of the diversity antenna with the directional antenna configured according to the present invention is to be implemented on the side of the fixed wireless transmission / reception apparatus, the fixed wireless transmission / reception apparatus side, that is, the base station of the wireless telephone is used. On the station side, it is not possible to use an anti-fading diversity antenna arrangement. This is because each directional antenna needs to be configured in duplicate. However, the function of the known anti-fading diversity antenna can be replaced in a mobile radio transmitting / receiving device, for example in the moving part of a radio telephone. That is, this function is limited to the moving part. Advantageous further developments of the method described in claim 1 are described in claims 2 to 4. Apparatuses and advantageous configurations and embodiments for carrying out the method according to the invention are described in claims 5 to 8. The invention and its important advantages will now be described with reference to nine drawings. All nine figures show the radiation distribution in one cutting plane, the horizontal cutting plane. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a diagram showing a radiation distribution of a known omnidirectional antenna. FIG. 2 is a diagram showing a radiation distribution of another known directional antenna. FIG. 3 is a diagram showing a radiation distribution of a known omnidirectional antenna, similarly to FIG. 1. FIG. 4 is a diagram showing a radiation distribution by a bidirectional antenna. FIG. 5 is a diagram showing a radiation distribution between a base station provided with an omnidirectional antenna and a mobile station. FIG. 6 is a diagram showing a radiation distribution between a base station having a directional antenna and a mobile station having an omnidirectional antenna. FIG. 7 is a view for explaining that the reception sensitivity of the base station or the mobile station can be adjusted in the case of FIG. 6; FIG. 8 is a view for explaining that transmission power of a base station or a mobile station can be reduced in the case of FIG. 6; FIG. 9 is a diagram illustrating that various advantages of the present invention can be integrated in a mobile station. BEST MODE FOR CARRYING OUT THE INVENTION FIG. 1 shows a known example. In this case, the transmission output of the fixed wireless transmission / reception device, for example, the base station of the wireless telephone is radiated uniformly around the periphery using the omnidirectional antenna 1. A wireless signal generated from a mobile radio transmitting / receiving device, for example, a moving part of a radio telephone, is equally received around the periphery by the fixed radio transmitting / receiving device. That is, the antenna 1 has a so-called circular radiation characteristic 2, and by this characteristic, an equal reach distance A can be achieved in each direction. If only a single point in time is observed, radiation is emitted in the direction of the fixed wireless transmitter / receiver, but almost the majority of the transmitted energy remains unused. On the other hand, FIG. 2 shows a divided state of a region indicated by a broken line, which has a reaching distance A in two subspaces. Each of these two subspaces is illuminated by one antenna 3 and 4 with directional characteristics 5 and 6, respectively, from the fixed radio transmitting / receiving device side. In this case, based on the formation of the diversity antenna, each one of the two directional antennas 3 and 4 is active in the subspace in which the mobile radio transmitting / receiving device is located. In the example shown in FIG. 2, since the reach distances A are equal, the transmission output and the reception sensitivity of the fixed device can be reduced. In the case of FIG. 3, as in FIG. 1, the omnidirectional radiation characteristic 2 of the antenna 1 of the fixed wireless transmitting / receiving device, for example the base station of the radio telephone, is indicated by the reach distance A, In FIG. 4, in the case of an active circuit, the same energy is radiated (in the case of transmission) or received in the same manner as in FIG. 1 via each of the two directional antennas 7 and 8, respectively. Sensitivity is obtained (for reception). At this time, the reach A ′ obtained in FIG. 4 can expand the free space by √2 times the reach A obtained in FIG. Furthermore, FIGS. 3 and 4 show the expected range gain for a diversity antenna implemented according to the invention and a constant transmission power / reception sensitivity. In the example based on FIG. 4, the antenna diagram 9 of the directional antenna 7 shown by a solid line is actively connected to the time shown, whereas the antenna diagram 10 of the directional antenna 8 shown by a broken line is Is not actively connected. This is because the mobile radio transmitting / receiving device is located in a partial radio space with a reach A 'covered by the directional antenna 7. Furthermore, it has been confirmed that the sum of the transmission powers on the hemisphere of the overlapping part matches the power radiated into this hemisphere. That is, the arrival distance is increased by √2 times due to the overlap of the transmission output. 5 to 9 illustrate the important advantages of the method according to the invention for a radio telephone consisting of a base station 11 and a mobile part 12. In the general case shown in FIG. 5, the base station 11 and the moving part 12 each have one antenna with omni-directional radiation characteristics 13 and 14. In this case, the distance B between the base station 11 and the moving part 12 is a distance at which wireless communication can be performed just before the arrival distance is provided in advance. FIG. 6 illustrates the use of an antenna with directivity 15 in the base station 11 for the same transmission power and reception sensitivity as in FIG. Is increased by a factor of √2 for free space propagation. In this case, the moving part 12 can be communicated from the base station 11 even at a distance far greater than the distance in FIG. 5, which was the actual distance before the present invention. When the method according to the present invention is not used for improving the reach as in the case of FIG. 6, the reception sensitivity of the base station 11 and the moving part 12 can be reduced. For this reason, it is generally possible to reduce costs. This case is shown in FIG. In other words, regions where the transmission signal does not fall below the reference level are indicated by solid lines, and regions where the transmission signal is received at the lowest reference level are indicated by broken lines. In this example, since the base station 11 is generated by the radiation output increased by the gain of the directional characteristic 16, the reception sensitivity of the moving part 12 can be reduced as indicated by the broken line. Conversely, when a signal is transmitted from the moving part 12 side, the reception sensitivity of the base station 11 can be similarly reduced by using a directional antenna at the base station 11. This is because the reduced directivity 17 is sufficient in order to receive the signal generated from the moving part 10 satisfactorily. If the method according to the invention is not used for increasing the range, the transmission power at the base station 11 and the mobile part 12 is instead reduced in order to reduce the reception sensitivity as described in FIG. be able to. This case is shown in FIG. In this case, the energy demand is small, so that the operation time of the battery-powered moving part 12 can be improved. In FIG. 8, an area where the transmission signal does not fall below the reference level is indicated by a solid line, and an area where the transmission signal is received at the lowest reference level is indicated by a broken line. In the case of transmission from the side of the base station 11, by using the directional pattern 18, a small transmission power is sufficient to reach the mobile station 12 by radio. On the other hand, when the signal is received by the base station 11, the transmission output of the moving part 12 can be reduced. This is because the base station 11 having the directivity 19 shown by the broken line has high reception sensitivity. It is very generally believed that interference radiation can be reduced by introducing a method according to the invention. That is, power is not radiated in a partial space where the moving portion 12 does not exist. That is, unrelated devices in this subspace are not disturbed. If the method of the invention is not used to increase the range, the transmission power of the moving part 12 can be reduced (as already explained). This can reduce the disturbing effect on unrelated devices around the moving part 12. It will now be necessary to explain, with reference to FIG. 9, that the various advantages of the method according to the invention can be integrated in the moving part 12. The transmission output and the reception sensitivity of the base station 11 do not change up to the antenna connection point. However, due to the directional characteristics 20 of the directional antenna that provides one gain in one partial radio space, the radiation output and reception sensitivity can be effectively improved in this partial radio space. By effectively increasing the transmission power of the base station 11, the reception sensitivity of the moving part 12 can be reduced. Since one base station 11 is configured to be able to hold contacts to a large number of moving parts, the cost of the receiver of the moving part 12 can be greatly reduced. By effectively increasing the reception sensitivity of the base station 11, it is also possible to reduce the transmission power of the moving part 12. This, on the one hand, reduces the power consumption of the moving part 12, ie the operating life of the moving part 12 is increased or a smaller and more convenient battery can be used. On the other hand, the disturbing effect on unrelated devices in the vicinity of the moving part 12 can be reduced. The one or more directional antennas of the fixed wireless transmitting / receiving device can be variously adjusted using a direction adjuster in an advantageous manner. As adjustable directional antennas it is possible to use advantageously so-called fast heading beam antennas, which are considered as further developments of vertical half-wave directional radiators and which each have four parasitic antennas. A single vertical half-wave directional radiator with elements, wherein the parasitic elements are arranged at a distance of 0.15λ (λ = wavelength) from the half-wave radiator, and Its length is switchable so that the half-wave radiator can selectively function as a director antenna or a reflector antenna. In this way, the directional radiator with the main radiator is correspondingly switched so that the radiator can radiate in all directions without mechanical rotation of the antenna. Is possible. The function of the quick heading beam antenna is almost the same as that of the three-element Yagi antenna.

Claims (1)

[Claims]   1. Caught by a mobile radio transmitting / receiving device with one antenna device Fixed wireless transmission / reception covering each partial wireless space Two or more directional antennas (3 , 4), and according to the formation of the diversity antenna, The directional antenna is excited, and a mobile radio transmission / reception device is provided in the partial radio space. Mobile radio communication device and fixed radio transmission / reception, A method for transmitting signals between devices.   2. Coverage by all directional antennas (3, 4) of the fixed wireless transmitter / receiver The sum of the sub-radio spaces to form a point-symmetric radio space The method of claim 1, wherein:   3. The orientation of the directional antennas (7, 8) can be done, for example, manually. The wireless space radiated from the antennas (7, 8) by the 2. The method according to claim 1, characterized in that it can be adapted to a building, for example. the method of.   4. The selection of the directional antennas (3, 4) to be excited respectively depends on the reception field strength. The fixed wireless transmission / reception device performs the comparison based on the comparison measurement of 4. The method according to any one of paragraphs 3 to 3.   5. Fixed radio transmitting / receiving device with two or more directivity antenna devices Antennas (3, 4) and the directional antennas (3, 4). Each one of the radio spaces captured by the fixed radio transmission / reception device. And the partial radio space where the mobile radio transmitting / receiving device is located The directional antennas are excited within each other. An apparatus for performing the method of any one of claims 4 to 10.   6. Direction adjustment device for directional antennas (7, 8) of fixed wireless transmitter / receiver 6. The method according to claim 5, wherein an arrangement is provided.   7. One measuring device is provided in the wireless transmitting / receiving device, and the measuring device is Using one mobile radio transmission that shines through individual directional antennas (3, 4). The received field strength of the signal coming from the signal / receiver is measured, and further the received field strength is measured. A comparison and selection device for determining the maximum value Make sure that the directional antenna for which the intensity exists can be excited. A method according to claim 5 or claim 6, characterized in that it is characterized by:   8. The directional antennas (7, 8) of the fixed wireless transmitting / receiving device are A beaming antenna, the antenna comprising four passive antennas. Consisting of a vertical half-wave radiator with an electrical element, wherein the parasitic element is Each is separated by 0.15λ (λ = wavelength) and its length is switched. The radiator can be a director antenna or a reflector antenna. 8. The apparatus according to claim 5, wherein said apparatus can selectively function as An apparatus according to any one of the preceding claims.